Title :
1000/spl deg/C operation of diamond Schottky diode
Author :
Vescan, A. ; Daumiller, I. ; Gluche, P. ; Ebert, W. ; Kohn, E.
Author_Institution :
Dept. of Electron Devices & Circuits, Ulm Univ., Germany
Abstract :
Due to the bandgap energy of 5.45 eV, the diamond intrinsic carrier concentration is 10/sup 10/cm/sup -3/ at 1000°C. This is a density found in Si at room temperature and similar device performance may be expected. On the other hand, a number of materials and fabrication difficulties have prevented such a demonstration up to now. The Schottky materials system presented here consisted of a chemically stabilized highly doped (quasi-metallic) Si interfacial layer to diamond, a nitrogen stuffed sputter deposited Si:W alloy and an Au overlap. The (W:Si)N diffusion barrier limited the use of the Au overlay to approximately 800°C. Without this overlayer operation up to 1000°C could be demonstrated. At 1000°C breakdown was observed at 30 V. However, similar devices have shown breakdown voltages up to 150 V at room temperature. A rectification ratio of Ion/Ioff=10 is maintained. To the authors knowledge this is the first demonstration of Schottky barrier operation at very high temperatures.
Keywords :
Schottky diodes; carrier density; diamond; electric breakdown; elemental semiconductors; (W:Si)N diffusion barrier; 20 to 1000 C; 30 to 150 V; 5.45 eV; Au; Au overlap; C; Schottky barrier; Schottky materials system; Si; Si:W; WSiN; bandgap energy; breakdown voltages; carrier concentration; diamond Schottky diode; high temperature operation; highly doped Si interfacial layer; rectification ratio; sputter deposited Si:W alloy; Breakdown voltage; Chemicals; Fabrication; Gold alloys; Nitrogen; Photonic band gap; Schottky barriers; Schottky diodes; Silicon alloys; Temperature;
Conference_Titel :
Device Research Conference Digest, 1997. 5th
Conference_Location :
Fort Collins, CO, USA
Print_ISBN :
0-7803-3911-8
DOI :
10.1109/DRC.1997.612467
